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Medium Bandgap Small Molecule Donors Compatible with Both Fullerene and Non-fullerene Acceptors Yong Huo, Cenqi Yan, Bin Kan, Xiao-Fei Liu, Li-Chuan Chen, Chen-Xia Hu, Tsz-Ki Lau, Xinhui Lu, Chun-Lin Sun, Xiangfeng Shao, Yongsheng Chen, Xiaowei Zhan, and Hao-Li Zhang ACS Appl. Mater. Interfaces, Just Accepted Manuscript • DOI: 10.1021/acsami.7b17961 • Publication Date (Web): 28 Feb 2018 Downloaded from http://pubs.acs.org on March 1, 2018

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ACS Applied Materials & Interfaces

Medium Bandgap Small Molecule Donors Compatible with Both Fullerene and Non-fullerene Acceptors

Yong Huo,1 Cenqi Yan,3 Bin Kan,4 Xiao-Fei Liu,1 Li-Chuan Chen,1 Chen-Xia Hu,1 Tsz-Ki Lau,5 Xinhui Lu,5 Chun-Lin Sun,1 Xiangfeng Shao,1 Yongsheng Chen,*4 Xiaowei Zhan*3 and Hao-Li Zhang*1,2 1

State Key Laboratory of Applied Organic Chemistry, Key Laboratory of Special

Function Materials and Structure Design, College of Chemistry and Chemical Engineering, Lanzhou University, Lanzhou 730000, China 2

Tianjin Key Laboratory of Molecular Optoelectronic Sciences, Department of

Chemistry, Tianjin University, and Collaborative Innovation Center of Chemical Science and Engineering (Tianjin), Tianjin 300072, P. R. China 3

Department of Materials Science and Engineering, College of Engineering, Key

Laboratory of Polymer Chemistry and Physics of Ministry of Education, Peking University, Beijing 100871, China 4

Key Laboratory of Functional Polymer Materials and the Centre of Nanoscale

Science and Technology, Institute of Polymer Chemistry, College of Chemistry, Nankai University, Tianjin 300071, China 5

Department of Physics, The Chinese University of Hong Kong, New Territories,

Hong Kong, China KEYWORDS: small molecule donor, fused-ring electron acceptor, compatibility, fullerene organic solar cell, non-fullerene organic solar cell 1

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Corresponding Author *H.-L. Zhang e-mail: [email protected] *X. Zhan e-mail: [email protected] *Y. Chen e-mail: [email protected] ABSTRACT Much effort has been devoted to the development of new donor materials for small molecule organic solar cells due to their inherent advantages of well-defined molecular weight, easy purification and good reproducibility in photovoltaic performance. Herein, we report two small molecule donors that are compatible with both fullerene and non-fullerene acceptors. Both molecules are consisted of a (E)-1,2-di(thiophen-2-yl)ethane (TVT) substituted benzo[1,2-b:4,5-b’]dithiophene (BDT)

as

the

central

unit,

and

two

rhodanine

units

as

the

terminal

electron-withdrawing groups. The central units are modified with either alkyl side chains (DRBDT-TVT) or alkylthio side chains (DRBDT-STVT). Both molecules exhibit medium bandgap with complementary absorption and proper energy level offset with typical acceptors like PC71BM and IDIC. The optimized devices show decent power conversion efficiency (PCE) of 6.87% for small molecule organic solar cells and 6.63% for non-fullerene all small molecule organic solar cells. Our results reveal that rationally designed medium bandgap small molecule donors can be applied in high performance small molecule organic solar cells with different type of acceptors.

2

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Introduction Organic solar cells (OSCs) have aroused considerable interest in the past few decades due to their many attractive features, such as solution-processablility, lightweight, flexibility and semitransparency.1-4 OSCs constructed with bulk heterojunction (BHJ) architectures contain donor and acceptor materials.5-6 Fullerene derivatives have been the predominant acceptor materials for decades. The superiority of the fullerene derivative acceptors includes excellent electron mobility, high electron affinity and easy formation of an appropriate phase separation with donor materials. The power conversion efficiencies (PCEs) of fullerene based OSCs have broken 10%.7-11 However, fullerene derivatives have inherent shortcomings including weak absorption in the visible region and nearly fixed energy levels, which limits the further improvement of photovoltaic performance.12-13 Recently, non-fullerene organic solar cells (NF-OSCs) have made rapid progresses partially owning to the fast devolvement of non-fullerene acceptor materials.14-18 Non-fullerene acceptors based on fused-ring electron acceptors (FREAs), such as ITIC19 and IDIC20, have met much success, due to their enhanced and broadened absorption in the visible to near-infrared region, optimal energy levels and less energy loss in the device.21-31 The over 13% PCEs record obtained from NF-OSCs even has surpassed those of fullerene based solar cells.32-33 Electron donor materials often employ electron rich conjugated polymers or small molecules.34-45 Early researches on donor materials have focused on polymer 3

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donors, while small molecule (SM) donors are drawing increasing attention in recent years. Compared with polymers, SM donors have several advantages, including good crystallinity, accurate molecular weight and well-defined chemical structure. Although the development of SM donors lagged behind the polymer ones in the early stages, PCEs of small molecule organic solar cells (SM-OSCs) have now reached over 11%, abreast to that of polymer solar cells.7,

46-47

For non-fullerene all small molecule

organic solar cells (NFASM-OSCs), though the best PCE has achieved about 10%,48-50 most cells can only give PCEs below 6%.3,

51-54

As SM donors with

excellent PCE performance are still limited in either SM-OSCs or NFASM-OSCs, significant efforts are being devoted to the design and synthesis of novel high performance SM donors for both SM-OSCs and NFASM-OSCs. In the past two decades, fullerene derivatives have been widely used as model acceptors in organic solar cells, in combination with a broad range of donor materials. In fact, the dominant role of fullerene acceptor in OSC research has allowed researchers to concentrate their efforts on donor materials and thus dramatically reduced the work load. Unlike the situation in acceptor materials, there are few types of SMs donor that be suitable for different acceptors. In literatures, most reported SM donors either exhibited low PCEs or showed better performance with one type of acceptors over the others.55-56 Developing a general type of SM donors that can work well with both fullerene acceptor and small molecule non-fullerene acceptor is highly desirable under current situation that more and more new acceptors are emerging. A widely applicable universal SM donor may not give the highest PCE, but could 4

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significantly simplify the efforts in material screening and device optimization. Moreover, developing SM donors that can match well with both fullerene and non-fullerene acceptors can also provide new insights to the relationship between material and performance. However, it is highly challenging to design SM donors compatible with both fullerene and non-fullerene acceptors, as they have different requirements in absorption spectra, energy level and morphology control.57 It is considered that a universal SM donor should meet the following criteria. First, it should have a medium optical bandgap to present complementary absorption with the common acceptors. Second, the highest occupied molecular orbital (HOMO) and lowest unoccupied molecular orbital (LUMO) should position appropriately compared with the fullerene or non-fullerene acceptors, in order to produce enough thermodynamic driving force for

charge

separation

and

to

reduce

the

energy

loss.

Third,

an

acceptor−donor−acceptor (A-D-A) or similar structure is necessary to enhance intramolecular charge transfer and to achieve high absorption coefficients. The molecules DRBDT-TVT and DRBDT-STVT (Figure 1) were designed under the above considerations. These molecules consist benzo[1,2-b:4,5-b’]dithiophene (BDT) moieties substituted by (E)-1,2-di(thiophen-2-yl)ethane (TVT) as the central building block, and the 3-ethylrhodanine as the ending electron-withdrawing group. BDT is a widely-applied conjugated moiety for building polymers and SM donors due to its symmetric and planar structure.58 For instance, Hou and Kang et al. reported that BDT units incorporating TVT side groups could lead to red-shifted and enhanced 5

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absorption, thereby boosted the short circuit current (JSC).59-60 Considering the recent reports that alkylthio substituent may down-shift the HOMO energy level and affect hole mobility,61-63 DRBDT-TVT and DRBDT-STVT were thus designed to have alkyl and alkylthio side chains, respectively. The 3-ethylrhodanine dye was incorporated herein because it has been successfully used as end group in many donor materials in consideration of its strong absorption and suitable electron-withdrawing property.64

Figure 1. Chemical structures of DRBDT-TVT and DRBDT-STVT.

In this work, both donors could work well with fullerene acceptor (PC71BM) and non-fullerene acceptor (IDIC), and produce the best PCE value of 6.87% for SM-OSCs and 6.63% for NFASM-OSCs, respectively. To the best of our knowledge, DRBDT-TVT and DRBDT-STVT are among the very few SM donors that can produce over 6.50% PCE in both fullerene and non-fullerene solar cells. Developing 6

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these universal SM donors may become a new promising entry point to improve the progress of OSCs.

Results and discussion Material Synthesis and Characterization. DRBDT-TVT

and

DRBDT-STVT

were

prepared

through

Knoevenagel

condensation of the dialdehyde intermediates with 3-ethylrhodanine in high yields, and the detailed synthetic procedures including characterization data are presented in Supporting Information (SI). The two SM donors exhibited good solubility in common solvents, such as chloroform, chlorobenzene (CB), and o-dichlorobenzene (o-DCB). Thermogravimetric analysis (TGA) (Figure S4)shows that both molecules possessed good thermal stability with decomposition temperatures (Td, 5% weight loss) of 378 ℃ and 385 ℃ , respectively. Density functional theory (DFT) calculations at B3LYP/6-31G* level were conducted to gain insight into the optimal molecular geometries of DRBDT-TVT and DRBDT-STVT (Figure S1). Side views of both molecules indicate linear backbones with good planarity. The dihedral angle between BDT and TVT side groups was 50.5° for DRBDT-STVT, slightly larger than the 47.6° of DRBDT-TVT.

7

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Figure 2. a) Chemical structures of PC71BM and IDIC; b) film absorption spectra of DRBDT-TVT, DRBDT-STVT, PC71BM and IDIC; c) energy level diagram of DRBDT-TVT, DRBDT-STVT, PC71BM and IDIC. Optical and Electrochemical Properties. The UV−vis absorption spectra of DRBDT-TVT and DRBDT-STVT in diluted CHCl3 solutions and solid films are illustrated in Figure S2 and Figure 2b, and the relevant data are summarized in Table 1. In solutions, DRBDT-TVT and DRBDT-STVT show broad and strong absorption from 300 to 600 nm and exhibit the maximum absorption peaks (λmax) at 460 and 480 nm, respectively, with nearly identical maximum absorption coefficient of 8.0 × 104 M−1 cm−1. Both molecules display red-shifted and broadened absorption spectra from solutions to films, suggesting strong intermolecular interactions between the conjugated backbones. The film absorption coefficients for DRBDT-TVT and DRBDT-STVT are 3.3 × 104 cm-1 and 3.1 × 104 cm-1, respectively. Compared with DRBDT-TVT, DRBDT-STVT has slightly blue-shifted absorption both in solution and film, which may be attributed to its larger dihedral angle between STVT side group and BDT unit that hinders 8

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molecular packing.63 The optical bandgaps of DRBDT-TVT and DRBDT-STVT are 1.75 and 1.76 eV, respectively. Cyclic voltammetry (CV) was employed to investigate the electrochemical properties of both molecules in dichloromethane solutions (Figure S3). The HOMO/LUMO levels are estimated to be -5.11/-3.41eV for DRBDT-TVT, and -5.14/-3.43 eV for DRBDT-STVT (Figure 2c). DRBDT-STVT shows down-shifted HOMO level attributing to the π-acceptor capability of the sulfur atom, which may lead to higher VOC in solar cell device.61-62 The bandgaps of DRBDT-TVT and DRBDT-STVT, calculated from the CV method, are 1.70 and 1.71 eV, respectively, in good agreement to their optical bandgaps.

Table 1. Optical and electrochemical data of DRBDT-TVT and DRBDT-STVT. SM Donors DRBDT-TVT DRBDT-STVT

λmax,sol

εsol

λmax,film

εfilm

(nm)

(M-1cm-1)

(nm)

(cm-1)

412,478 416,462

4

8.0×10

4

8.0×10

587,632 588,630

Egopt

HOMO

LUMO

Egcv

(eV)

(eV)

(eV)

(eV)

4

1.75

-5.11

-3.41

1.70

4

1.76

-5.14

-3.43

1.71

3.3×10 3.1×10

Photovoltaic Properties. The PC71BM and IDIC were chosen as the representative acceptors to fabricate devices, and their chemical structure are depicted in Figure 2a. It was expected that DRBDT-TVT and DRBDT-STVT should work well with these two acceptors based on the following facts: First, the film absorption of DRBDT-TVT and DRBDT-STVT are in the range of 400-700 nm, which is complementary to the absorption in the ranges of 300-500 nm for PC71BM and 500-800 nm for IDIC. Second, the HOMO/LUMO levels of DRBDT-TVT and DRBDT-STVT are higher than those of 9

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PC71BM and IDIC. The proper LUMO offsets provide effectively driving force for charge separation. Third, IDIC exhibits a good electron mobility (µe = 1.1 × 10-3 cm2 V-1 s-1),20 which is close to the hole mobility of DRBDT-TVT (µh = 8.5 × 10−4 cm2 V−1 s-1) and DRBDT-STVT (µh = 7.1 × 10−4 cm2 V−1 s-1) as measured by space charge limited current (SCLC) method (Figure S5), ensuring efficient and balanced charge transport in the blend film.

Figure 3. (a) J-V characteristics and (b) EQE spectra of the optimized OSCs with SVA treatment under illumination of AM 1.5 G at 100 mW cm−2.

Table 2 Device parameters of the optimized SM-OSCs and ASM-OSCs under the illumination of AM 1.5G, 100 mW cm-2.

a

FF

PCEc

JSCcal

(mA cm )

(%)

(%)

(mA cm-2)

0.879

10.73

72.76

DRBDT-STVT:PC71BMa

0.907

10.25

73.61

DRBDT-TVT:IDICb

0.840

12.22

64.58

DRBDT-STVT:IDICb

0.887

10.93

67.17

Blends

VOC (V)

DRBDT-TVT:PC71BMa

JSC -2

6.87 (6.67 ± 0.20) 6.84 (6.61 ± 0.23) 6.63 (6.45 ± 0.18) 6.51 (6.25 ± 0.25)

10.28

10.22

11.75

10.53

with CS2 SVA treatment for 30s. b with THF SVA treatment for 30s. c average data are obtained from 20 devices.

The conventional devices of ITO/PEDOT:PSS/SM donors:PC71BM/PrC60MA/Al 10

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for SM-OSCs and ITO/PEDOT:PSS/SM donors:IDIC/PDIN/Al for NFASM-OSCs were fabricated to evaluate the photovoltaic performance of DRBDT-TVT and DRBDT-STVT. The J-V curves and external quantum efficiency (EQE) spectra are shown in Figure 3 and the corresponding device parameters are summarized in Table 2. For PC71BM cells, the as-cast devices based on DRBDT-TVT and DRBDT-STVT showed moderate PCEs of 6.27% and 5.86%, respectively, along with relatively low

JSC. After solvent vapor annealing (SVA) treatment with CS2 for 30 s, the PCEs of DRBDT-TVT and DRBDT-STVT based devices increased to 6.87% and 6.84%, respectively, with increased JSC and excellent fill factor (FF) over 70%. For IDIC cells, the as-cast devices based on DRBDT-TVT and DRBDT-STVT yielded relatively low PCEs of 3.54% and 3.37%, respectively, with very low JSC and FFs. After SVA treatment with THF for 30 s, the PCEs of DRBDT-TVT and DRBDT-STVT based devices raised to 6.63% and 6.51%, respectively, with significantly improved JSC and FFs. Table 1 showed that the VOC of the as-cast IDIC cells were closely to that of the as-cast PC71BM cells for same donor, consistent with the similar LUMO levels of PC71BM and IDIC. Compared with the optimized PC71BM cells, the optimized IDIC cells gave higher JSC originated from their stronger photoresponse in near-infrared region. However the FFs of the optimized IDIC cells were slightly poor, implied that charge recombination was more obvious though most of charge recombination was effectively suppressed in the all four types of devices.65 Compared with the DRBDT-TVT based devices, the DRBDT-STVT based devices revealed slightly poor PCEs with lower JSC despite the larger VOC and FFs both in fullerene and 11

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non-fullerene solar cells. The higher VOC of the DRBDT-STVT based devices was attributed to the lowered HOMO level by introduction of sulfur atoms. The lower JSC of DRBDT-STVT based devices may be due to its slightly poorer absorption and larger lamellar packing distance as discussed blow. The calculated JSC obtained by integration of the EQE curves is listed in Table 2, which is in good agreement with the JSC value measured from the J-V curves (the error is